ITCO20130004A1 - METHOD TO REALIZE A IMPELLER FROM SECTOR SEGMENTS - Google Patents

Description

METHOD FOR MAKING AN IMPELLER FROM SECTOR SEGMENTS

Field of the invention

The present invention relates to a method for producing a centrifugal compressor impeller.

State of the art

Generally an impeller for a centrifugal rotating machine, such as a centrifugal compressor, is composed of an approximately disc-shaped main body, which has a front and a rear surface, with reference to the direction of fluid flow, provided with a circular hole center housing a hub connected to a rotating axle, a fairing equipped with a front and a rear surface, arranged at an interval towards the outside of the main body, and a series of vanes that couple to the front surface of the main body and to the rear surface of the fairing. A series of passages consists of the front surface of the main body, the rear surface of the fairing and the side surfaces of the vanes, where the passages serve as a flow passage for compressing air. Generally, the vanes follow a curved line that bends in both radial and axial directions. The front surface of the main body and the rear surface of the fairing curve accordingly to contain the curvature of the vanes. The airflow enters the impeller tangential to the front surface of the main body and exits the impeller in an axial direction. A fairing impeller can be produced from a single block of material or, alternatively, it can be constructed using two or more components linked together to form the finished product. Generally the different components are fixed by welding. The impeller can be built from a single block by solid milling, but this is a very complex and time-consuming process given the limited accessibility due to the complex shape of the flow passages. The electro-erosion process (EDM) is another option for the fabrication of the single piece by erosion with removal of the metal by electric sparks. In this process an electric spark is used as a cutting tool to erode the single monolithic disc, to produce the finished part with the designed shape. The metal removal process is performed by applying a pulsating (ON / OFF) electrical charge of high frequency current to the workpiece through the electrode. With this technique, the machining of the single piece includes the steps of preliminary milling, EDM roughing and EDM finishing. For the reason indicated above, to adapt to the complex series of steps, it is necessary to use electrodes and instruments of a particular shape. The process takes a long time and many days of work to produce a single impeller. The impeller can also be produced by first manufacturing two components, or by making the blades by milling the main body or the fairing, and welding the two parts at a later time. With welding, the filling of the internal joint between the vanes and the main body or fairing is very difficult, given the lack of good accessibility; welding defects easily occur during fixing and, therefore, the risk of breakages and deformations, or the thermal distortion caused by locally high temperatures, can become very high. In addition, the surfaces of the flow passage will generally not exhibit the required uniformity. In conclusion, it is very difficult, using state of the art techniques, to obtain an impeller with the high quality and reliability that it would require. For these reasons, there is an urgent need for a method of making a high quality impeller, resulting in shorter production times and lower costs.

Summary of the invention

It follows that a main object of the present invention consists in providing a new method of manufacturing an impeller, which is simple and requires shorter processing times. Another object of the present invention consists in the realization of a production method of an impeller of high quality and reliability. A further object of the invention is to provide a centrifugal compressor impeller compatible with a state-of-the-art production technique.

And a further object of the invention consists in the realization of a method which allows to realize an impeller with complex geometries.

Therefore the present invention achieves the aforementioned objectives by means of a method of manufacturing an impeller for a centrifugal rotating machine which, according to claim 1, is composed of an approximately disc-shaped main body equipped with a front and a rear surface, a fairing equipped with a front and a rear surface disposed at a distance from the front surface of the main body, a plurality of vanes connected to the front surface of the main body joining the main body with the fairing, where the lateral surfaces of the vanes, the front surface of the body and the rear surface of the casing form flow passages for compressing air, in which case the method comprises making individual impeller segments consisting of a single blade, a body section and the corresponding section of the casing, and the subsequent union of the plurality of segments for form the impeller.

A further aspect of the invention provides an impeller for a centrifugal rotating machine according to claim 11.

The individual segments can be advantageously produced by material addition production methods, such as direct laser melting (DMLM). The individual segments are advantageously joined together by welding or friction welding. Furthermore, the individual sectors may not be joined together, but be connected to the hub or directly to the shaft through mechanical joints or welding. The individual sectors or the entire impeller can advantageously be connected to the hub by means of mechanical joints such as dovetail joints.

Brief description of the figures

Further features and advantages of the invention will become more evident in the light of a detailed description of a preferred, but not exclusive, embodiment of an impeller for rotating machines, illustrated by means of non-limiting examples, with the aid of the drawings enclosed in the Which:

Fig. 1 is a perspective view of an impeller according to the invention;

Fig. 2 is an exploded view of a cross section of an impeller before being fixed to the hub;

Fig. 3 shows a cross section of the impeller joined to the hub;

Fig. 4 represents a single segment of the impeller mounted on the hub;

Fig. 5 is a perspective view of a segment of an impeller according to another embodiment of the invention;

Fig. 6 is a perspective view of an impeller containing the segments illustrated in Fig. 5.

Same reference numbers, recurring in different figures, represent identical elements or components.

Detailed description of a preferred embodiment of the invention Referring to Figures 1 and 2, a perspective representation of a 3D impeller is provided, generally indicated by the reference number 100. The impeller 100 consists of a main body disk-shaped 3 with a rear surface and a front surface 7. The front surface 7, starting from an outer circular portion almost flat and perpendicular to the axis of rotation Z of the machine, gradually curves towards the central region in the direction of Z axis, where the central region is a circular opening adapted to mate with the outer surface of hub 1 or rotor shaft. A fairing 5, which roughly reproduces the shape of the front surface 7 of the body 3, is separated from this front surface by the vanes 4. The air passages 6, through which the air is compressed, consist of the internal surface of the fairing. , from the front surface 7 of the body 3 and from the side surfaces of the vanes 4. In this type of impeller for centrifugal compressor, the air flow enters the passages tangentially to the flat surface of the body, in the direction of the rotation axis, and exits in an almost vertical direction and parallel to said axis of rotation, by the circular passage formed between the front surface 7 of the body and the internal surface of the fairing. Fig. 2 shows an exploded sectional view of this type of impeller, with hub 1 shown as a separate element to be inserted into the central region of body 3. Hub 1 is connected to the rotor shaft of the machine. Fig. 3 shows the final assembly of the impeller with the insertion of the hub 1. The vanes 4 therefore the air passages 6 generally have a complex shape. As observed in Figs. 1 and 2, they follow a curved path not only in the axial direction, but are also set back in relation to the direction of rotation of the impeller. These characteristics of the impeller make the milling and welding work very complex and laborious, even if special tools are used, capable of being inserted and used in the aforementioned air passages 6. These difficulties are to the detriment of good accuracy, roughing surfaces and time. The present invention is based on the segmentation principle aimed at overcoming these disadvantages. Fig. 4 is a representation of this technique. The idea basically consists in the realization of single segments of an impeller where each segment can, for example, contain a single blade, and join them to assemble the impeller by welding or a mechanical locking system. The segments can be joined together or can be attached separately to the shaft. In Fig. 4 the reference 100 'indicates one of these segments which must be welded to the hub 1. The segment is composed of a fairing segment 5 and a segment of the main body 3 joined by a vane 4. In Fig. 4 Ã You can also see the complex shape of the palettes and steps. Segmentation solves the accessibility problem entirely. The impeller can be made by joining together the individual segments 100 'by external laser welding and then joining the segments welded to the hub or directly to the rotor shaft by means of cold metal transfer (CMT). The finished product is obtained after the passage of heating and turning.

It is also possible to fix the single elements one by one to the hub, as shown in Fig. 4, or directly on the rotor shaft. The segment 100 'can be connected to the hub or directly to the rotor shaft also by means of a mechanical locking system, as illustrated in Figs. 5 and 6. Fig. 5 shows a segment which, on the side facing the external surface of the hub, has a dovetail joint 8 with inclined side walls. These dovetail joints 8 slide engaging an identical and corresponding dovetail-shaped groove 10, illustrated in Fig. 6, constituted on the external surface of the hub. Fig. 6 represents a perspective sectional view of an impeller made by means of the present mechanical locking system. The impeller can be assembled on the hub as a single piece with the segments joined together by welding and then sliding the hub into the center or by sliding the segments, one by one, into the dovetail grooves of the hub. When using the mechanical locking system, the single segment can be provided with a groove 9 on the surface of the rear flat side of the body 3 (Figs. 5 and 6) which, when the impeller is assembled, forms a circular groove which can be equipped with a ring to secure the segments together. The production of a single pallet segment is not only simple, fast and cost-effective, but allows for the use of state-of-the-art manufacturing technologies, such as the use of composite material or techniques such as direct laser melting (DMLM), in which a laser melts metal powder into a solid, three-dimensional part with a process of adding material, layer by layer. Compared to the many days it takes to make an impeller using one of the known technologies, such as electro-erosion (EDM), which requires a preliminary milling step followed by EDM roughing and EDM finishing, the assembly of pre-fabricated individual blade segments takes only a few hours , with considerable savings in time and costs, without considering the improvement in terms of quality. The construction of the impeller by assembling individual blade segments, given the simplicity of manufacture and the high versatility of the process, also allows the design and manufacture of a flow path of innovative, high-performance, cutting-edge geometries that, at the moment, they are not yet achievable.

Claims (13)

CLAIMS 1. Method of manufacturing an impeller (100) for a centrifugal rotating machine which is composed of a roughly disc-shaped main body (3) having a front and a rear surface, a fairing (5) having a front surface (7) and a rear one arranged at a distance from the front surface of the main body (3), a plurality of vanes (4) connected to the front surface (7) of the main body (3) joining the main body (3) with the fairing ( 5), where the lateral surfaces of the vanes (4), the front surface (7) of the body (3) and the rear surface of the fairing (5) constitute flow passages (6) for compressing the air, in which case the method comprises the initial realization of single segments (100â € ™) of the impeller (100) comprising a single blade (4), a section of the main body (3) and the corresponding section of the fairing (5), and the subsequent joining of the plurality d the segments to form the impeller (100). Method according to claim 1, wherein the segments (100 ') are joined together by welding or friction welding. Method according to claim 2, wherein the impeller is connected to a hub (1) which is connected to a rotor shaft of the machine or directly connected to the rotor shaft. Method according to claim 3, wherein the impeller is connected to the hub (1) or directly to the rotor shaft by CMT deposition. Method according to claim 1, wherein the individual segments (100 ') are connected to the hub or directly to the rotor shaft of the machine. Method according to claim 5, wherein the segments (100 ') are connected to the hub (1) or to the rotor shaft by welding or friction welding or by means of a mechanical locking system. 7. Method according to claim 6, wherein the mechanical locking system comprises dovetail joints. Method according to claim 3, wherein the impeller is connected to the hub or rotor shaft by dovetail joints. Method according to claims 7 or 8, wherein the segments are fastened together by a ring located in a groove (9) formed on the rear surface of the main body (3). Method according to claim 1, wherein the single segment (100 ') is produced by direct laser melting. 11. Impeller (100) for a centrifugal rotating machine consisting of an approximately disc-shaped main body (3) equipped with a front and a rear surface, a fairing (5) equipped with a front (7) and a rear surface arranged at a distance from the front surface of the main body (3), a plurality of vanes (4) connected to the front surface (7) of the main body (3) joining the main body (3) with the fairing, whereas the lateral surfaces of the vanes ( 4), the front surface (7) of the body (3) and the rear surface of the casing (5) constitute flow passages (6) for compressing the air, in which case the impeller is composed of single segments (100â € ™) consisting of a single vane (4), a section of the main body (3) and the corresponding section of the fairing (5), where the individual segments are joined together or fixed to the hub or directly to the rotor shaft. Impeller according to claim 11, wherein the individual segments (100 ') have a dovetail joint (8) with inclined side surfaces on the side facing the outer surface of the hub (1). 13. Impeller according to claim 12, wherein the hub (1) has on the external surface dovetail grooves (10) with inclined surfaces, which establish a coupling relationship with the dovetail-shaped joints (9) of the segments ( 100â € ™).